The Truth About Alfred Wegner

My name is Ned Malone and I am a journalist. I have interviewed many great men in my time. Professor Challenger, the great scientist who explored the Lost World. Captain Nemo, amazing explorer of ocean depths. Charles Darwin, who some call the father of modern biology. But none who have changed science the way Alfred Wegener has managed to change science.

Born on November 1, 1880, Alfred Wegener earned a Ph.D in from the University of in 1904. However, he had always been interested in , and also became fascinated with the developing fields of and . Wegener was also a tutor and professor at variou s German universities.

In 1911, while at , Wegener was browsing in the university library when he came across a scientific paper that listed fossils of identical and animals found on opposite sides of the Atlantic. Intrigued by this information, Wegener began to look for, and find, more cases of similar organisms separated by great oceans.

Orthodox science at the time explained such cases by postulating that land bridges, now sunken, had once connected far-flung . But Wegener noticed the close fit between the coastlines of Africa and South America. Might the similarities among organisms be due, not to land bridges, but to the continents having been joined together at one time? As he later wrote: "A conviction of the fundamental soundness of the idea took root in my mind."

Such an insight, to be accepted, would require large amounts of supporting evidence. Wegener continued to collect this evidence and in 1915 published The Origin of Continents and Oceans, a book outlining his Theory of . In his book, he claimed that about 300 million years ago the continents had formed a single mass, called (from the Greek for "all the Earth"). Pangaea had rifted, or split, and its pieces had been moving away from each other ever since. This meteorologist was not the first to suggest that the continents had once been connected, but he was the first to present extensive evidence from several fields. As a non-geologist, Wegener's trespass into the discipline of was not welcomed. A supporter later explained, of his problems in gaining a hearing: “To work on subjects which fall outside the traditionally defined bounds of a science naturally exposes one to being regarded with mistrust". Throughout his career he was an outsider in the field; and although it gave him the ability to see beyond the entrenched ideas of the science, it also opened him to mistrust and criticism. At that time, scientists kept well within the bounds of their own specialties.

Not only did biologists keep Artwork of Alfred Wegener discussing with away from the earth Dr Werner Janensch with a map and dinosaur sciences, but even skull on a table in front of them geophysics, geology and had been totally separated, with no connection between these obviously-related disciplines or their specialists. Wegener's work that reconnected them was derided throughout his lifetime, and he himself was ostracized by the narrow geological community.

Reaction to Wegener's theory was almost uniformly hostile, and often exceptionally harsh and scathing; Dr. Rollin T. Chamberlin of the University of Chicago said, "Wegener's hypothesis in general is of the footloose type, in that it takes considerable liberty with our globe, and is less bound by restrictions or tied down by awkward, ugly facts than most of its rival theories."

Part of the problem was that Wegener had no convincing mechanism for how the continents might move. Wegener thought that the continents were moving through the earth's crust, like icebreakers plowing through ice sheets, and that centrifugal and tidal forces were responsible for moving the continents. Opponents of continental drift noted that plowing through oceanic crust would distort continents beyond recognition, and that centrifugal and tidal forces were far too weak to move continents -- one scientist calculated that a tidal force strong enough to move continents would cause the Earth to stop rotating in less than one year.

Another problem was that flaws in Wegener's original data caused him to make some incorrect and outlandish predictions: he suggested that North America and Europe were moving apart at over 250 cm per year (about ten times the fastest rates seen today, and about a hundred times faster than the measured rate for North America and Europe).

Indeed, there were scientists who supported Wegener: the South African geologist supported it as an explanation for the close similarity of strata and fossils between Africa and South America, and the Swiss geologist Émile Argand saw continental collisions as the best explanation for the folded and buckled strata that he observed in the Swiss Alps.

Unfortunately, before his theory was ever fully accepted, Wegner died. Throughout his studies, Wegner had made many trips to . Wegener made what was to be his last expedition to Greenland in 1930. While returning from a rescue expedition that brought food to a party of his colleagues camped in the middle of the Greenland icecap, he died, a day or two after his fiftieth birthday.

Wegener's theory continued to find scattered support after his death, but the majority of geologists continued to believe in static continents and land bridges.

Finally, in the 1950’s, increased exploration of the Earth’s crust and ocean floor revealed that Wegner’s basic ideas were valid – the continents did move. However, so does the crust of the ocean floor.

Alfred Wegner was a man who stretched the bounds of science. His theory was rejected partially because in formulating it he had straying outside of the narrowly-defined field in which he was expected to work. However, once accepted, that same theory broadened and enriched many diverse fields, not only those of geophysics, geology, geography and evolution, but also oceanography, biology and zoology.

PROFILE Harry Hess: One of the Discoverers of Harry Hess (1906–1969) in his World War II Naval uniform. Photo courtesy of Princeton University, Department of Geosciences.

Nothing could feel more solid than the ground under our feet. Yet the surface of the Earth is not fixed, but rather broken up like a jigsaw puzzle into enormous plates that move. This process is called , and it transformed the thinking of geologists. One of them, Harry Hess, was an instrumental figure in figuring out how plate tectonics worked.

Hess possessed two valuable skills: careful attention to detail and the ability to form sweeping hypotheses. This unusual combination produced groundbreaking work on a number of subjects, including the origin of ocean basins and island arcs, mountain building, and the movement of continents. The idea that the continents might have moved, or “drifted” over time can be traced back to the sixteenth century, when European cartographers compiled world maps based on the seagoing expeditions of that time. This idea was transformed into the theory of “continental drift” by German meteorologist Alfred Wegener in 1912, when he published a treatise with several lines of supporting evidence that went beyond simply matching the continents like puzzle pieces. These lines of evidence included, for example, matching geological formations and paleontological distributions from South America and Africa. Wegener’s critics correctly pointed out, however, that the continents could not simply “plow” though the ocean floor as Wegener had vaguely theorized. It was Hess who determined how oceanic mountain ranges, called mid- ocean ridges, are fundamental to the tectonic movement that results in the drift of continents.

According to his own account, Hess flunked his first course in mineralogy at Yale and was told he had no future in the field. Nevertheless he stuck with it, and was teaching geology at Princeton when World War II was declared. Already a lieutenant junior grade in the Naval Reserve, Hess was called to active duty after Pearl Harbor and was eventually to rise to the rank of Rear Admiral. He soon developed a system for estimating the daily positions of German U- boats in the North Atlantic, and requested duty aboard a decoy vessel in order to test the program. It worked.

He then served as commander of the attack transport U.S. Cape Johnson in the Pacific Ocean, taking part in major landings at Marianas, Leyte, Lingayen Gulf, and Iwo Jima. Ever the scientist, while cruising from one battle to the next, Hess kept the transport’s sounding gear (which bounced sound waves off the sea-floor in order to determine the underwater relief or topography) running day and night. This led to his discovery of submerged and curiously flat- topped mountains that he named “guyots” in honor of the Swiss founder of the Princeton geology department. It also produced thousands of miles of echo-sounding surveys of the ocean floor.

The postwar period was a revolutionary one for the earth sciences. Efforts to map the ocean floor intensified, thanks in large part to the newly-created U.S. Office of Naval Research. Within a few years, a curious terrain had emerged: vast, flat plains interrupted by ridges, or more precisely, vast mountain ranges. In the Atlantic Ocean, the “ridge” is about midway between the continents on either side, and thus it became known as a mid-ocean ridge. We now know that the ocean ridge system snakes around the entire globe in a continuous chain some 80,000 kilometers long. In 1953, scientists discovered that a prominent valley, called the Great Global Rift, ran down the center of these ridges. Intrigued, Hess reexamined the data from a completely fresh, unorthodox perspective. In 1962, he proposed a groundbreaking hypothesis that proved vitally important in the development of plate tectonic theory. It addressed several geologic puzzles: If the oceans have existed for at least 4 billion years, why has so little sediment accumulated on the ocean floor? Why are fossils found in ocean sediments no more than 180 million years old? And how do the continents move?

Hess theorized that the ocean floor is at most only a few hundred million years old, significantly younger than the continents. This is how long it takes for molten rock to ooze up from volcanically active mid-ocean ridges, spread sideways to create new seafloor, and disappear back into the Earth’s deep interior at the ocean trenches. This “recycling” process, later named “seafloor spreading,” carries off older sediment and fossils, and moves the continents as new ocean crust spreads away from the ridges.

Supporting Wegener’s theory of continental drift, Hess explained how the once-joined continents had separated into the seven that exist today. The continents don’t change dramatically or move independently, but are transported by the shifting tectonic plates on which they rest. The theory also explained Hess’s puzzling guyots. They are believed to be once-active volcanoes that rose above the surface like modern-day island arcs and then were eroded to sea level. As the ocean crust spread away from the higher ocean ridges, the guyots sank below sea level, becoming completely submerged. Hess also theorized that because the continental crust was lighter, it didn’t sink back into the deep earth at trenches as did the oceanic crust. Instead, it scraped rock off the descending ocean crust and piled it into mountain rages at the trenches’ edge. Hess also incorporated the idea proposed by Swiss geologist Emile Argand in the 1920s that mountain belts are also created when two continents collide.

Hess’s bold intuition was subsequently corroborated. Later studies showed that the age of the ocean floor increases with distance from the ridge crests, and seismic studies confirmed that the oceanic crust was indeed sinking into the trenches. His report, History of Ocean Basins, was formally published in 1962 and for some time was the single most referenced work in solid-earth geophysics.

Hess also contributed significantly to his university, where he became head of the Princeton geology department, and was an important member of the national scientific community. He helped design the national space program, and was one of ten members of a panel appointed to analyze rock samples brought back from the Moon by the Apollo 11 crew. He died in August, 1969, a month after Apollo 11’s successful mission. A National Academy of Sciences memoir calls Hess “one of the truly remarkable earth scientists of this century.”